JP2022185918A - Hot water storage type hot water supply device - Google Patents

Abstract

To provide a hot water storage type hot water supply device that is advantageous in increasing energy efficiency.SOLUTION: A hot water storage type hot water supply device is equipped with a hot water storage tank, heating means that heats water taken out from the hot water storage tank, and control mean that controls a boiling-up operation in which hot water flowing out from the heating means is caused to flow into the hot water storage tank. As the boiling-up operation, a normal boiling-up operation and a high-temperature boiling-up operation in which a boiling-up temperature that is a temperature of the hot water flowing out from the heating means is higher than that of the normal boiling-up operation can be executed. In a surplus power boiling-up operation that is a boiling-up operation using surplus power of generated power of a photovoltaic power generator, first, the normal boiling-operation is executed, and then the high-temperature boiling-up operation after the execution of the normal boiling-up operation is executed.SELECTED DRAWING: Figure 6

Description

The present disclosure relates to a hot water storage type hot water supply apparatus.

2. Description of the Related Art There is known a hot water storage type hot water supply apparatus capable of performing a boiling operation with surplus electric power out of electric power generated by a solar power generation apparatus. The hot water storage type hot water supply apparatus disclosed in Patent Document 1 below sets the boiling temperature when performing the boiling operation with surplus electric power to be higher than the boiling temperature when performing the boiling operation using commercial power at night. is configured as

Japanese Patent No. 6289440

The higher the boiling temperature, the lower the COP or coefficient of performance of the heat pump unit. In addition, the higher the boiling temperature, the greater the loss of heat that is lost through piping until the hot water that has exited the heat pump unit returns to the hot water storage tank. Also, the higher the boiling temperature, the greater the heat loss that is lost while the hot water is being stored in the hot water storage tank. For these reasons, there is a problem that if the boiling temperature is raised during the boiling operation using surplus electric power, it is difficult to increase the energy efficiency.

The present disclosure has been made to solve the problems described above, and an object of the present disclosure is to provide a hot water storage type hot water supply apparatus that is advantageous in increasing energy efficiency.

A hot water storage type hot water supply apparatus according to the present disclosure includes a hot water storage tank, a heating means for heating water taken out from the hot water storage tank, a control means for controlling a boiling operation in which hot water discharged from the heating means flows into the hot water storage tank, and, as the boiling operation, normal boiling operation and high temperature boiling operation in which the boiling temperature, which is the temperature of the hot water flowing out of the heating means, is higher than the normal boiling operation can be performed, and the solar In the surplus electric power boiling operation, which is a boiling operation using the surplus electric power out of the power generated by the photovoltaic power generation device, the normal boiling operation is first performed, and after the normal boiling operation is performed, the high temperature boiling operation is performed. is.

Advantageous Effects of Invention According to the present disclosure, it is possible to provide a hot water storage type hot water supply apparatus that is advantageous in increasing energy efficiency.

1 is a diagram showing a hot water storage type hot water supply apparatus according to Embodiment 1. FIG. 1 is a diagram showing an example of a configuration of a controller for a hot water storage type hot water supply apparatus according to Embodiment 1; FIG. FIG. 4 is a diagram showing an example of fluctuations in PV power generation amount, water heater power consumption amount, and in-home power consumption amount in one day. FIG. 4 is a diagram schematically showing a state during high-temperature boiling operation; It is a figure which shows the relationship between Legionella spp. and water temperature. 4 is a flowchart showing an example of processing executed by the control device when the hot water storage type hot water supply apparatus according to Embodiment 1 performs a surplus electric power boiling operation; FIG. 4 is a diagram showing an example of change in temperature distribution in the hot water storage tank from the start to the end of the boiling operation in the daytime; 2 is a Mollier diagram of the heat pump circuit of the hot water storage type hot water supply apparatus according to Embodiment 1. FIG. FIG. 4 is a diagram showing an example of fluctuations in PV power generation amount, water heater power consumption amount, and in-home power consumption amount in one day.

Embodiments will be described below with reference to the drawings. Elements that are common or correspond to each figure are denoted by the same reference numerals, and their explanations are simplified or omitted. In the following description, the terms "water", "hot water", and "hot water" basically mean liquid water, and can include cold water to hot water.

Embodiment 1.
FIG. 1 is a diagram showing the configuration of a hot water storage type hot water supply apparatus 1 according to Embodiment 1. As shown in FIG. As shown in FIG. 1 , a hot water storage type hot water supply apparatus 1 of the present embodiment includes a heat pump unit 2 , a hot water storage tank 3 , and a boiling circuit 4 . The heat pump unit 2 is an example of heating means for heating water. The hot water storage tank 3 is covered with a heat insulating material (not shown).

Inside the hot water storage tank 3, temperature stratification is formed in which the upper side has a higher temperature and the lower side has a lower temperature due to the difference in the density of the water according to the temperature. The capacity of the hot water storage tank 3 is not particularly limited, but may be in the range of 200L to 600L, for example.

The hot water storage tank 3 in this embodiment has a single container. As a modification, the hot water storage tank 3 may have a structure in which a plurality of containers are connected in series via pipes. In the plurality of vessels, the lower part of the vessel on the higher side of the temperature stratification, ie, the higher temperature side, communicates with the upper part of the vessel on the lower side of the temperature stratification, ie, the lower temperature side, by a pipe. In the following description, the upper portion, middle portion, and lower portion of the hot water storage tank 3 will be described. means a hierarchy of containers in total.

Water supplied from a water source such as a tap water flows into the lower part of the hot water storage tank 3 . As a result, the inside of the hot water storage tank 3 is maintained in a full water state. The water supplied from the water source may be hereinafter referred to as "low temperature water".

The hot water storage tank 3 has an upper opening 3c, a lower outlet 3d, and an intermediate outlet 3e. The intermediate outlet 3e is located higher than the lower outlet 3d and lower than the upper outlet 3c. In this embodiment, the hot water storage tank 3 has an upper outlet 3c, a lower outlet 3d, and an intermediate outlet 3e between the upper and lower portions of the hot water tank 3. There is

The boiling circuit 4 has a forward water channel 6 , a return water channel 7 and a circulation pump 8 . The incoming water channel 6 connects the lower outlet 3 d or the middle outlet 3 e of the hot water storage tank 3 to the water inlet of the heat pump unit 2 . The return water channel 7 connects the hot water outlet of the heat pump unit 2 to the upper opening 3 c of the hot water storage tank 3 . In the illustrated example, a circulation pump 8 is provided in the going water channel 6 . A circulation pump 8 may be provided in the return water line 7 instead of the illustrated example.

A plurality of stored hot water temperature sensors 5 are attached to the hot water storage tank 3 . The plurality of stored hot water temperature sensors 5 are arranged at different height positions. Each of the plurality of hot water storage temperature sensors 5 detects the water temperature in the hot water storage tank 3 . A plurality of stored hot water temperature sensors 5 correspond to temperature distribution detection means for detecting the temperature distribution of the temperature stratification formed in the hot water storage tank 3 . In the following description, the temperature distribution of temperature stratification formed in the hot water storage tank 3 is referred to as "hot water temperature distribution". In addition, the amount of heat stored in the hot water storage tank 3 may be referred to as "hot water storage amount". The amount of stored hot water may be expressed, for example, in units of joules or calories, or may be expressed in units of volume [L] of hot water converted to hot water at a predetermined temperature (eg, 42° C.).

Storage-type hot water supply device 1 further includes a control device 10 . The control device 10 corresponds to control means for controlling the operation of the hot water storage type hot water supply device 1 . The control device 10 controls the boiling operation. Note that the present disclosure is not limited to the configuration in which the operation of the hot water storage type hot water supply apparatus 1 is controlled by a single control device 10 as in the example shown in the drawing, and a plurality of control devices cooperate to control the operation of the hot water storage type hot water supply device 1 . The configuration may be such that the operation of the water heater 1 is controlled.

The boiling operation, for example, operates as follows. The control device 10 operates the heat pump unit 2 and the circulation pump 8 . The water flowing out from the lower outlet 3 d of the hot water storage tank 3 flows into the heat pump unit 2 through the incoming water passage 6 . The hot water heated by the heat pump unit 2 passes through the return water channel 7 and flows into the hot water storage tank 3 from the upper port 3c.

In the present embodiment, the temperature of hot water flowing out of the heat pump unit 2 during the boiling operation is referred to as "boiling temperature". Further, the volumetric flow rate of water flowing through the boiling circuit 4 is hereinafter referred to as "boiling flow rate". The control device 10 may detect the boiling flow rate using a flow rate sensor (not shown). Alternatively, the control device 10 may store the correlation between the rotation speed of the circulation pump 8 and the boiling flow rate, and calculate the boiling flow rate from the rotation speed of the circulation pump 8 .

A hot water storage type hot water supply apparatus 1 according to the present embodiment has a configuration in which a hot water storage unit 9 including a hot water storage tank 3, a circulation pump 8, and the like and a heat pump unit 2 are separated. The hot water storage unit 9 and the heat pump unit 2 are connected via a heat pump water inlet pipe 18, a heat pump hot water outlet pipe 19, and an electric cable (not shown). The hot water storage unit 9 is connected to a bathtub unit 80 having a bathtub 81 in the bathroom of the house via a bathtub going piping 82 and a bathtub returning piping 83 . The hot water storage unit 9 further includes a plurality of valves, which will be described later.

The hot water storage type hot water supply device 1 further includes a remote controller 11 . Two-way communication is possible between the control device 10 and the remote controller 11 by wired communication or wireless communication. Remote control 11 and control device 10 may be able to communicate via a network. Remote controller 11 is an example of a user interface. The remote controller 11 may have, for example, a display unit such as a liquid crystal panel that displays information, and an operation unit that is operated by the user. The remote controller 11 may have a touch screen that functions as both a display unit and an operation unit. By operating the remote controller 11, a person such as a user can remotely control the hot water storage type hot water supply apparatus 1 and perform various settings. For example, the remote controller 11 is provided with a function that allows the user to set the temperature of the hot water supply, a function that allows the user to set the temperature and amount of hot water to be discharged to the bathtub 81, and a function that allows the user to set the reheating temperature of the bathtub water. good too.

The display unit of the remote control 11 has a function as a notification means for notifying information to people such as users. The remote controller 11 may be installed, for example, on the wall of the kitchen, living room, bathroom, or the like. A plurality of remote controllers 11 may be installed at different locations. In addition to the remote control 11, a smart speaker or a television installed at home may be configured to be used as a user interface, or a mobile terminal such as a smartphone may be configured to be used as a user interface. may In principle, in the following description, the remote control 11 and other user interfaces are collectively referred to simply as "remote control 11". That is, in the following description, processing using the remote control 11 can be replaced with processing using other user interfaces.

The user can operate the remote controller 11 to fill the bathtub 81 with hot water at around 40° C., for example. The bathtub 81 is connected to the bath heat exchanger 12 in the hot water storage unit 9 via a bathtub return pipe 83 and a bathtub outgoing pipe 82 . The bath heat exchanger 12 exchanges heat between hot water from the bathtub 81, that is, bathtub water, and the heat medium.

Bathtub 81 has drain plug 84 . When time elapses and the bath heat is radiated in the bathroom and the temperature of the hot water in the bathtub 81 drops, the hot water taken out from the upper part of the hot water storage tank 3 is supplied to the bath heat exchanger 12 as a heat medium, A reheating operation of heating the hot water from the bathtub 81 in the bath heat exchanger 12 is possible with the heat medium.

The heat pump unit 2 includes a compressor 13 , a refrigerant-water heat exchanger 14 , an expansion valve 15 , an outdoor heat exchanger 16 and an outdoor heat exchanger fan 17 . Driving of each of these devices is controlled by the control device 10 . A suction side of the compressor 13 is connected to an outdoor heat exchanger 16 . A discharge side of the compressor 13 is connected to a refrigerant-water heat exchanger 14 . The control device 10 may variably control the rotation speed of the compressor 13 by inverter control, for example. As the refrigerant circulating in the refrigerant circuit of the heat pump unit 2, for example, R32, fluorocarbon, carbon dioxide, or the like can be used.

The controller 10 may change the rotational frequency of the compressor 13 to adjust the refrigerant flow rate and control the heating capacity of the heat pump unit 2 . The heating capacity of the heat pump unit 2 corresponds to the amount of heat given to water by the heat pump unit 2 per unit time. The control device 10 may calculate the optimum target heating capacity value each time the boiling operation is performed.

The outdoor heat exchanger 16 is a heat exchanger that exchanges heat between the refrigerant and the air sent from the outdoor heat exchanger fan 17 and evaporates the gas-liquid refrigerant with the heat of the air. A refrigerant inlet side of the outdoor heat exchanger 16 is connected to the expansion valve 15 . A refrigerant outlet side of the outdoor heat exchanger 16 is connected to the compressor 13 .

The refrigerant-water heat exchanger 14 is for heating the hot water in the hot water storage tank 3 . The heat pump water inlet pipe 18 connects the c port of the three-way valve 28 in the hot water storage unit 9 to the water inlet of the refrigerant-water heat exchanger 14 . A circulation pump 8 is connected in the middle of the heat pump water inlet pipe 18 inside the hot water storage unit 9 . The heat pump hot water outlet pipe 19 connects the hot water outlet of the refrigerant-water heat exchanger 14 to the b port of the four-way valve 20 in the hot water storage unit 9 .

A heat pump circuit composed of a compressor 13, an outdoor heat exchanger 16 and an expansion valve 15 is connected to the refrigerant-water heat exchanger . In the refrigerant-water heat exchanger 14, the refrigerant of the heat pump circuit and the hot water supplied from the hot water storage tank 3 flow in opposite directions to each other. The refrigerant-water heat exchanger 14 exchanges heat between the refrigerant of the heat pump circuit and the hot water supplied from the hot water storage tank 3, and heats the hot water to a target boiling temperature (for example, 45° C. to 90° C.).

The outdoor heat exchanger fan 17 is arranged in front of the outdoor heat exchanger 16, sends air into the outdoor heat exchanger 16, and promotes heat exchange between the air and the refrigerant. The controller 10 determines the rotation speed of the outdoor heat exchanger fan 17 .

The hot water storage unit 9 includes a bathtub circulation pump 22, a hot water supply end 23 connected to an external pipe (not shown) for supplying hot water to a hot water supply destination such as a kitchen or washroom faucet or a bathroom shower, and a tap water supply. It further comprises a water supply end 24 to which an external water supply pipe (not shown) for supplying water from a water source is connected. In the hot water storage unit 9 , the water supply pipe 27 connects the water supply end 24 to the a port of the three-way valve 29 . A tank water supply pipe 31 branched from the water supply pipe 27 is connected to the lowest portion 3 b of the hot water storage tank 3 . A pipe 32 connects a lower outlet 3 d at the bottom 3 b of the hot water storage tank 3 to the a port of the three-way valve 28 .

One end of a hot water supply pipe 26 is connected to an upper port 3c at the uppermost portion 3a of the hot water storage tank 3. As shown in FIG. The other end of hot water supply pipe 26 communicates with hot water supply pipe 25 . The hot water storage tank 3 is connected to a boiling circuit 4, a hot water supply circuit, a hot water filling circuit, and a reheating circuit. The configuration of each circuit will be described later.

As described above, hot water can be circulated in the boiling circuit 4 by the circulation pump 8 during the boiling operation. Further, in the present embodiment, hot water in the hot water storage tank 3 can be circulated to the bath heat exchanger 12 by the circulation pump 8 when the bathtub 81 is reheated. During the reheating operation, when the circulation pump 8 operates, the hot water in the hot water storage tank 3 circulates to the bath heat exchanger 12 via the hot water introduction pipe 33 and the hot water discharge pipe 34 .

The bath heat exchanger 12 heats the hot water in the bathtub 81, and is composed of a tube-type or plate-type heat exchanger. Tubular heat exchangers include, for example, spiral heat exchangers. Plate heat exchangers include, for example, plate heat exchangers. The bath heat exchanger 12 is connected to the upper portion of the hot water storage tank 3 by a hot water introduction pipe 33 . The bath heat exchanger 12 is connected to the b port of the three-way valve 28 by a hot water outlet pipe 34 . The bath heat exchanger 12 is connected to a bath circulation circuit in which hot water in a bath 81 is circulated by a bath circulation pump 22 . During the reheating operation, the bath heat exchanger 12 heat-exchanges hot water in the bathtub 81 circulating in the bathtub circulation circuit with high-temperature water introduced from the upper part of the hot water storage tank 3 through the hot water introduction pipe 33. Thus, the hot water in the bathtub 81 is heated, and the temperature of the hot water in the bathtub 81 is maintained or raised.

The bathtub circulation pump 22 is connected in the middle of the bathtub return pipe 83 . Hot water in the bathtub 81 is also called bathtub water. During the reheating operation, the bathtub circulation pump 22 circulates the bathtub water between the bath heat exchanger 12 and the bathtub 81 through the bathtub return pipe 83 and the bathtub going pipe 82 .

Each of the bath hot water mixing valve 35 and the general hot water mixing valve 36 has a first inlet, a second inlet, and an outlet. The downstream side of the hot water supply pipe 25 branches into two and communicates with the first inlets of the bath hot water mixing valve 35 and the general hot water mixing valve 36 . An outlet of the bath hot water supply mixing valve 35 is connected to a bathtub going piping 82 via a hot water filling piping 37 . An outlet of the general hot water supply mixing valve 36 is connected to the hot water supply end 23 via a general hot water supply pipe 39 .

The three-way valve 28 is flow path switching means having ports a and b serving as inlets and a port c serving as an outlet. The three-way valve 28 is configured to be switchable between two paths of ac and bc.

The three-way valve 29 is flow path switching means having ports a and b serving as inlets and a port c serving as an outlet. The three-way valve 29 is configured to be switchable between two paths of ac and bc. The b port of the three-way valve 29 is connected to the intermediate outlet 3e via the medium-temperature water pipe 40. As shown in FIG. An upstream end of a water supply pipe 41 is connected to the c port of the three-way valve 29 . The downstream side of the water supply pipe 41 branches into two and communicates with the second inlets of the bath hot water mixing valve 35 and the general hot water mixing valve 36 .

When the three-way valve 29 is set to ac, the low-temperature water from the water supply end 24 can flow through the water supply pipe 27 and the water supply pipe 41 into the second inlets of the bath hot water mixing valve 35 and the general hot water mixing valve 36, respectively. Become. When the three-way valve 29 is set to bc, medium-temperature water in the hot water storage tank 3 passes through the intermediate outlet 3e, the medium-temperature water pipe 40, and the water supply pipe 41 to the bath hot water mixing valve 35 and the general hot water mixing valve 36. It becomes possible to flow into each of the second inlets. The three-way valve 29 may be configured to adjust the mixing ratio of the low-temperature water from the water supply pipe 27 and the medium-temperature water from the medium-temperature water pipe 40 .

The bath hot water mixing valve 35 adjusts the mixing ratio of the high temperature water from the hot water supply pipe 25 and the low temperature or medium temperature water from the water supply pipe 41 by changing the opening degree of the valve, thereby controlling the hot water filling temperature. It is. The hot water filling open/close valve 38 is provided on the hot water filling pipe 37 and switches between starting and stopping the hot water filling of the bathtub 81 by opening and closing.

The general hot water supply mixing valve 36 adjusts the mixing ratio of the high temperature water from the hot water supply pipe 25 and the low temperature or medium temperature water from the water supply pipe 41 by changing the opening of the valve, and discharges hot water from the hot water supply end 23. It controls the temperature.

One end of a hot water lead-out pipe 42 is connected to a position in the middle of the intermediate hot water pipe 40 . The other end of the hot water lead-out pipe 42 is connected to a midpoint of the hot water lead-out pipe 34 .

The four-way valve 20 is flow path switching means having ports a and b serving as inlets and ports c and d serving as outlets. The four-way valve 20 is configured to be switchable between four paths ac, ad, bc, and bd. The four-way valve 30 is flow path switching means having a port as an inlet and ports b, c, and d as outlets. The four-way valve 30 is configured to be switchable between three paths ab, ac, and ad.

The a port of the four-way valve 20 is connected to the heat pump water inlet pipe 18 between the discharge port of the circulation pump 8 and the refrigerant-water heat exchanger 14 via the water pipe 43 . The c port of the four-way valve 20 is connected to the lower part of the hot water storage tank 3 via the first hot water pipe 44 . The d port of the four-way valve 20 is connected to the a port of the four-way valve 30 via the second hot water pipe 45 . The b port of the four-way valve 30 is connected to a position in the middle of the hot water introduction pipe 33 via the third hot water pipe 46 . The c port of the four-way valve 30 is connected to the intermediate portion of the hot water storage tank 3 via the fourth hot water pipe 47 . The d port of the four-way valve 30 communicates with the hot water supply pipe 25 and the hot water supply pipe 26 via the fifth hot water pipe 48 .

A plurality of stored hot water temperature sensors 5 are arranged at intervals in the vertical direction of the hot water storage tank 3 . By receiving the temperature information detected by the stored hot water temperature sensor 5 , the control device 10 calculates the stored hot water temperature distribution and the amount of hot water stored in the hot water storage tank 3 . A controller 10 instructs the heat pump unit 2 and the hot water storage unit 9 to continue the boiling operation until the amount of hot water stored in the hot water storage tank 3 reaches a target amount.

The incoming water temperature sensor 49 is attached to the heat pump incoming water pipe 18 or the inlet of the refrigerant-water heat exchanger 14 and detects the temperature of the water before being heated by the refrigerant-water heat exchanger 14 . The outlet hot water temperature sensor 50 is attached to the heat pump outlet hot water pipe 19 or the outlet of the refrigerant-water heat exchanger 14, and detects the temperature of the hot water after being heated by the refrigerant-water heat exchanger 14, that is, the boiling temperature. Temperature information from the incoming water temperature sensor 49 and the outgoing hot water temperature sensor 50 is sent to the control device 10 . In the boiling operation, the control device 10 adjusts either the rotation speed of the circulation pump 8 or the operation of the heat pump unit 2 so that the actual boiling temperature detected by the outlet hot water temperature sensor 50 becomes equal to the target boiling temperature. control one or both.

The bathtub temperature sensor 51 detects the temperature of the bathtub water flowing into the bath heat exchanger 12 via the bathtub return pipe 83 . Temperature information from the bathtub temperature sensor 51 is sent to the control device 10 . When the temperature of the bathtub water detected by the bathtub temperature sensor 51 becomes lower than the user set temperature, the controller 10 instructs the hot water storage unit 9 and the bathtub unit 80 to start the reheating operation. The bathtub-going temperature sensor 52 detects the temperature of the bathtub water that passes through the bath heat exchanger 12 and flows through the bathtub-going piping 82 to the bathtub 81 . Temperature information is sent to the control device 10 through the tub-going piping 82 . The control device 10 issues an instruction to the hot water storage unit 9 and the bathtub unit 80 so that the heated bathtub water reaches the user set temperature during the reheating operation.

The hot water supply flow rate sensor 53 is provided on the general hot water supply pipe 39 and detects the hot water supply flow rate. A detected value of hot water supply flow rate sensor 53 is transmitted to control device 10 . Control device 10 uses the detected value of hot water supply flow rate sensor 53 when calculating the hot water supply load. Hot water supply temperature sensor 55 is provided on general hot water supply pipe 39 and detects the temperature of hot water supply.

The hot water filling flow rate sensor 54 is provided on the hot water filling pipe 37 and detects the hot water filling flow rate. A detection value of the hot water filling flow rate sensor 54 is transmitted to the control device 10 . The controller 10 uses the detected value of the hot water filling flow rate sensor 54 when calculating the hot water filling load.

The control device 10 learns the hot water supply load, the hot water filling load, and the reheating load for each day of the past several days (for example, the past 14 days), so that the hot water supply load and the hot water load for the next day are learned. The tension load amount and the reheating load amount may be predicted for each time zone. During the reheating operation, the control device 10, for example, detects the temperature detected by the bathtub temperature sensor 51, the temperature detected by the bathtub forward temperature sensor 52, and the flow rate of the bathtub water estimated from the rotation speed of the bathtub circulation pump 22. may be used to calculate the reheating load.

The boiling circuit 4 in the present embodiment can be switched between a lower outlet for taking out water in the hot water tank 3 from the lower outlet 3d and an intermediate outlet for taking out water from the hot water tank 3 from the intermediate outlet 3e. be.

The bottom extraction boiling circuit 4 is formed by opening the three-way valve 28 in the ac direction, the four-way valve 20 in the bd direction, and the four-way valve 30 in the ad direction. The lower outlet boiling circuit 4 communicates with the refrigerant-water heat exchanger 14 from the lower outlet 3d via the three-way valve 28 and the heat pump water inlet pipe 18, and connects the heat pump hot water outlet pipe 19, the second hot water pipe 45, and the second hot water pipe 45. It is a circuit connected to the upper port 3c via the five hot water pipes 48 and the hot water supply pipes 26.

The boiling circuit 4 for taking out the intermediate portion is formed by opening the three-way valve 28 in the bc direction, the four-way valve 20 in the bd direction, and the four-way valve 30 in the ad direction. The boiling circuit 4 for taking out the intermediate part is supplied from the intermediate part outlet 3e via the medium temperature water pipe 40, the hot water outlet pipe 42, the hot water outlet pipe 34, the three-way valve 28, and the heat pump water inlet pipe 18. It is a circuit that communicates with the water heat exchanger 14 and is connected to the upper port 3 c via the heat pump hot water supply pipe 19 , the second hot water pipe 45 , the fifth hot water pipe 48 and the hot water supply pipe 26 .

The hot water supply circuit includes a circuit that communicates with the general hot water supply mixing valve 36 via the hot water supply pipe 26 and the hot water supply pipe 25 from the upper part of the hot water storage tank 3, and a water supply pipe 27 from the water supply end 24, three directions opened in the ac direction. It has a circuit communicating with the general hot water mixing valve 36 via the valve 29 and the water supply pipe 41 and a circuit communicating from the general hot water mixing valve 36 to the hot water supply end 23 via the general hot water supply pipe 39 .

The hot water filling circuit has a circuit that communicates from the upper part of the hot water storage tank 3 to the bath hot water mixing valve 35 via the hot water supply pipe 26 and the hot water supply pipe 25 . The hot water filling circuit includes a circuit connected from the water supply end 24 to the lower part of the hot water storage tank 3 via the tank water supply pipe 31, a water supply pipe 27 from the water supply end 24, and a three-way valve 29 opened in the ac direction. and a circuit that communicates with the bath/hot water mixing valve 35 via the water supply pipe 41 . Furthermore, the hot water filling circuit has a circuit that connects from the bath hot water supply mixing valve 35 to the bathtub 81 via the hot water filling pipe 37 , the hot water filling opening/closing valve 38 and the bathtub going pipe 82 .

The reheating circuit is formed by opening the three-way valve 28 in the bc direction and by opening the four-way valve 20 in the ac direction. The reheating circuit communicates with the bath heat exchanger 12 from the upper part of the hot water storage tank 3 via the hot water supply pipe 26 and the hot water introduction pipe 33, and passes through the hot water outlet pipe 34, the water pipe 43, and the first hot water pipe 44. It is a circuit connected to the lowest part of the hot water storage tank 3.

The bathtub circulation circuit has a bath heat exchanger 12 , a bathtub circulation pump 22 , and a bathtub 81 , and is connected by a bathtub return pipe 83 and a bathtub going pipe 82 . Bathtub water is circulated in the bathtub circulation circuit by a bathtub circulation pump 22 .

The hot water supply operation is started in response to a hot water use operation at the hot water supply destination. In the hot water supply operation, in the hot water supply circuit, the hot water stored in the hot water storage tank 3 is led out from the upper part of the hot water storage tank 3 or the middle part of the hot water storage tank 3 according to the hot water use at the hot water supply destination, and the general hot water supply mixing valve 36 sent to Low-temperature tap water is led from the water supply end 24 to the general hot water supply mixing valve 36 via the water supply pipe 27, and is mixed with hot water from the hot water storage tank 3 to a set temperature. is supplied to the hot water supply destination. The low-temperature water supplied from the water supply end 24 in accordance with the decrease in the hot water drawn out from the upper part or the middle part of the hot water storage tank 3 passes through the water supply pipe 27 and the tank water supply pipe 31 to the lowest part in the hot water storage tank 3. 3b will automatically flow. As tap water is supplied to the lowermost portion 3b in the hot water storage tank 3 in this manner, the temperature boundary layer moves upward in the hot water storage tank 3 .

The hot water filling operation is started by the user operating the remote controller 11 . At this time, the filling opening/closing valve 38 is opened. In the hot water filling operation, in the hot water filling circuit, hot water stored in the hot water storage tank 3 is led out from the upper portion of the hot water storage tank 3 or the middle portion of the hot water storage tank 3 and sent to the bath hot water mixing valve 35 . Low-temperature tap water is led from the water supply end 24 to the bath hot water mixing valve 35 via the water supply pipe 27, and is mixed with the hot water from the hot water storage tank 3 to be adjusted to an appropriate temperature. The hot water is supplied to the bathtub 81 through which hot water is filled. Hot water filling is stopped when the water level in the bathtub 81 reaches a set value. The water level in the bathtub 81 is detected by a water level sensor (not shown) installed in the bathtub circulation circuit. The water level sensor detects the water level by measuring pressure changes with a pressure sensor mounted on the water level sensor.

The reheating operation is forcibly started by the user operating the remote controller 11 . Alternatively, when a drop in the temperature of the hot water in the bathtub 81 is detected, the reheating operation is automatically started. When the reheating operation is started, the operation of the circulation pump 8 and the bathtub circulation pump 22 is started. In the reheating operation, high-temperature water drawn from the upper part of the hot water storage tank 3 in the reheating circuit is led to the bath heat exchanger 12 . At approximately the same time as this timing, the hot water stored in the bathtub 81 is led to the bath heat exchanger 12 through the bathtub return pipe 83 . In the bath heat exchanger 12 , heat is exchanged between high-temperature tank water from the hot water storage tank 3 and bathtub water from the bathtub 81 . The tank water, the temperature of which has been lowered by applying heat to the bathtub water, passes through the hot water lead-out pipe 34, the three-way valve 28, the circulation pump 8, the water pipe 43, the four-way valve 20, the second hot water pipe 45, the four-way valve 30, and the fourth hot water. It returns to the hot water storage tank 3 through the pipe 47 . Bathtub water whose temperature has been increased by receiving heat from the bath heat exchanger 12 returns to the bathtub 81 through the tub-going piping 82. - 特許庁When the controller 10 detects that the bathtub water temperature detected by the bathtub temperature sensor 51 has reached the target bathtub temperature, the controller 10 issues a reheating stop command to stop the operation of the bathtub circulation pump 22 and the circulation pump 8. Let Thus, in the reheating operation, an operation is performed to raise the bathtub water in the bathtub 81 to the target bathtub temperature.

A solar power generation device (not shown) is installed in a home having the hot water storage type hot water supply device 1 of the present embodiment. Below, the said household is simply called a "household." A solar power generation device includes a solar cell or the like that receives sunlight and generates power. The DC power generated by the photovoltaic power generation device is converted into AC power by a power conditioner (not shown) and supplied to homes. The hot water storage type hot water supply device 1 in the home and electric devices other than the hot water storage type hot water supply device 1 can be operated by electric power generated by the solar power generation device.

Electric power is supplied to homes from the commercial power supply of the electric power company during the hours when the photovoltaic power generation device does not generate power. Further, when the power generated by the solar power generation device is insufficient for the household power consumption during power generation by the solar power generation device, the shortage of power is supplied from the commercial power source to the home. Hereinafter, power supplied from a commercial power supply to homes is referred to as "commercial power".

During power generation by the solar power generation device, if the power generated by the solar power generation device is greater than the total power consumption of electrical appliances in the home other than the hot water storage type hot water supply device 1, the surplus power is used to store hot water. The hot water supply apparatus 1 can perform the boiling operation. Below, the boiling-up operation using surplus electric power is called "surplus electric-heating operation."

The amount of power generated per hour by the photovoltaic power generation device is hereinafter referred to as "PV power generation amount". Further, the power consumption per hour of the hot water storage type hot water supply apparatus 1 is hereinafter referred to as "water heater power consumption". Further, the amount of electric power consumption per hour of electric appliances in the home other than the hot water storage type hot water supply apparatus 1 is referred to as "in-home electric power consumption". A value obtained by subtracting the in-house power consumption from the PV power generation amount is referred to as "surplus power amount".

FIG. 2 is a diagram showing an example of the configuration of control device 10 of hot water storage type hot water supply apparatus 1 according to Embodiment 1. As shown in FIG. Control device 10 controls each part provided in hot water storage type hot water supply device 1 . In the example shown in FIG. 2, the control device 10 has an information acquisition section 10a, an arithmetic processing section 10b, a device control section 10c, a communication section 10d, a timer 10e, and a storage section 10f. The control device 10 may implement various functions by executing software on an arithmetic device such as a microcomputer. Alternatively, the control device 10 may be configured by hardware such as a circuit device that implements various functions.

The information acquisition unit 10a includes various sensors such as a hot water storage temperature sensor 5, an incoming water temperature sensor 49, an outgoing hot water temperature sensor 50, a bathtub temperature sensor 51, an outgoing bathtub temperature sensor 52, a hot water supply flow rate sensor 53, a hot water filling flow rate sensor 54, a hot water supply temperature sensor 55, and the like. Sensor detection information and device operation information such as the number of revolutions of the circulation pump 8 are acquired. Further, the information acquisition unit 10 a acquires information on the current surplus power amount from the power supply circuit connected to the hot water storage type hot water supply apparatus 1 .

There is an electricity rate system in which the unit price of electricity when purchasing commercial power becomes cheaper in the middle of the night. Hereinafter, the late-night hours when the unit price of power is cheaper may be referred to as "nighttime", and the hours other than "nighttime" may be referred to as "daytime". The specific time zones of "nighttime" and "daytime" differ depending on the electricity rate system and the like. As an example, the time period from 23:00 to 7:00 may be defined as "night" and the time period from 7:00 to 23:00 may be defined as "daytime."

After the load for the day ends, the arithmetic processing unit 10b calculates the hot water supply load and A nighttime target heat storage amount corresponding to the hot water filling load, a daytime target heat storage amount corresponding to the hot water supply load and hot water filling load, and a target heat storage amount of hot water corresponding to the reheating load may be determined. In this case, the target heat storage amount for nighttime and the target heat storage amount for daytime are determined according to the predicted values of the hot water supply load and the hot water filling load. The target heat storage amount of high-temperature water corresponding to the reheating load is determined according to the predicted value of the reheating load amount.

The arithmetic processing unit 10b calculates the start condition, the end condition, the target heating capacity, and the boiling temperature for each of the nighttime boiling operation and the daytime boiling operation, based on the target heat storage amount determined above and the surplus You may judge according to the situation of electric energy.

The device control unit 10c controls the compressor 13, the expansion valve 15, the three-way valve 28, the three-way valve 29, the four-way valve 20, the four-way valve 30, the bath/hot water mixing valve 35, and the hot water supply according to the processing result of the arithmetic processing unit 10b. It controls the on-off valve 38 , the general hot water supply mixing valve 36 , the circulation pump 8 and the bathtub circulation pump 22 .

The communication unit 10d is connected to the remote controller 11 for wired communication or wireless communication, and transmits and receives information to and from the remote controller 11 . Moreover, when HEMS (home energy management system) is installed in the home, the communication unit 10d may communicate with the HEMS and receive information on the amount of surplus power. Further, the communication unit 10d may receive, from the HEMS, information related to prediction of the amount of surplus power for the next day, such as weather forecast information for the next day.

The timer 10e counts the current time, and outputs a signal indicating that the set time has come when the set time has come. Further, the timer 10e transmits time information upon request from the arithmetic processing unit 10b.

The storage unit 10 f stores various values used in each unit of the control device 10 . For example, the storage unit 10f stores a target heat storage amount for night time, a target heat storage amount for daytime, a target heat storage amount for reheating load, and a hot water storage amount currently stored in the hot water storage tank 3 for heat storage amount management. Remember.

In the present embodiment, control device 10 can perform normal boiling operation and high temperature boiling operation as boiling operation. The high-temperature boiling operation is an operation in which the boiling temperature is higher than that of the normal boiling operation. The boiling temperature in the normal boiling operation is preferably less than 65°C, more preferably less than 55°C, and even more preferably less than 50°C. The boiling temperature in the normal boiling operation may be, for example, 45°C. The boiling temperature in the high temperature boiling operation is preferably 65°C or higher. The boiling temperature in the high temperature boiling operation may be, for example, 65°C.

In the surplus power boiling operation, the control device 10 first executes the normal boiling operation, and after executing the normal boiling operation, executes the high temperature boiling operation. When the normal boiling operation is executed, hot water having a temperature equivalent to the boiling temperature of the normal boiling operation is generated in the hot water storage tank 3 . The hot water generated by the normal boiling operation is hereinafter referred to as "intermediate hot water". After that, when the high temperature boiling operation is executed, hot water having a temperature equivalent to the boiling temperature of the high temperature boiling operation is generated in the hot water storage tank 3 . The hot water generated by the high temperature boiling operation is hereinafter referred to as "high temperature water". In the hot water storage tank 3 after the surplus electric power boiling operation ends, there is high-temperature water in the upper part, and medium-temperature water is in the lower part of the high-temperature water.

According to the present embodiment, the following effects can be obtained by first executing the normal boiling operation with a low boiling temperature in the surplus electric power boiling operation. Since the boiling temperature is low, the COP improvement effect that the COP of the heat pump unit 2 is high, and the piping heat dissipation that the amount of heat lost by dissipating while the hot water discharged from the heat pump unit 2 passes through the heat pump hot water supply piping 19 is reduced. A loss reduction effect and a tank heat radiation loss reduction effect that the amount of heat dissipated and lost while hot water is stored in the hot water storage tank 3 is reduced can be obtained. From these things, energy efficiency becomes high.

Further, in the surplus electric power boiling operation, high temperature water can be generated in the upper part of the hot water storage tank 3 by executing the high temperature boiling operation after executing the normal boiling operation. At the time of the reheating operation, by supplying this high-temperature water to the bath heat exchanger 12 as a heat medium, the amount of heat exchanged in the bath heat exchanger 12 can be sufficiently increased, and appropriate reheating operation is possible. becomes. If the high-temperature boiling operation is not executed, there is no high-temperature water in the upper part of the hot water storage tank 3 and there is only medium-temperature water. will supply. Then, in the bath heat exchanger 12, the temperature difference between the medium hot water as a heat medium and the bath water from the bath tub 81 is small, so the amount of heat exchange cannot be sufficiently increased, and an appropriate reheating operation is performed. is difficult.

The control device 10 may set the boiling temperature during the nighttime boiling operation to be lower than the boiling temperature during the high-temperature boiling operation. By lowering the boiling temperature, the COP improvement effect, the piping heat radiation loss reduction effect, and the tank heat radiation loss reduction effect described above can be obtained. The boiling temperature during the nighttime boiling operation may be the same as the boiling temperature during the normal boiling operation.

During execution of the surplus electric power boiling operation, the control device 10 may change the heating capacity of the heat pump unit 2 according to changes in surplus electric power. When the heating capacity of the heat pump unit 2 is changed, the power consumption of the hot water storage type hot water supply device 1 is changed. Control device 10 may change the heating capacity of heat pump unit 2 so that the power consumption of storage-type hot water supply apparatus 1 does not exceed the surplus power. By changing the heating capacity of the heat pump unit 2 in accordance with the change in the surplus power, it is possible to reliably prevent the purchase of commercial power, which is advantageous in reducing the electricity bill.

The normal boiling operation is started by an instruction to start operation from the control device 10 to the heat pump unit 2 and the circulation pump 8 . In the heat pump unit 2, the compressor 13 is activated and the refrigerant circulates in the heat pump circuit. The refrigerant compressed by the compressor 13 and then discharged flows into the refrigerant-water heat exchanger 14, exchanges heat with hot water sent from the hot water storage tank 3, and is cooled. The cooled refrigerant is decompressed by the expansion valve 15 and then flows into the outdoor heat exchanger 16 . The refrigerant that has flowed into the outdoor heat exchanger 16 exchanges heat with the air from the outdoor heat exchanger fan 17 to be heated, and then returns to the compressor 13 .

On the other hand, in the hot water storage unit 9, the control device 10 forms a boiling circuit 4 with a bottom extraction. Then, by driving the circulation pump 8, the low-temperature water in the lower part of the hot water storage tank 3 is taken out from the lower outlet 3d and sent to the refrigerant-water heat exchanger 14 via the heat pump water inlet pipe 18. In the refrigerant-water heat exchanger 14, the low-temperature water is heated to the target boiling temperature by heat exchange with the refrigerant of the heat pump circuit to generate hot water, that is, medium-temperature hot water. The target boiling temperature at this time is less than 65°C, for example, 45°C, as described above. The generated hot water, that is, intermediate hot water flows into the upper part of the hot water storage tank 3 via the heat pump hot water outlet pipe 19 , the second hot water pipe 45 and the fifth hot water pipe 48 . As the normal boiling operation progresses, inside the hot water storage tank 3, medium temperature water accumulates in the upper side, and the temperature boundary layer between the lower low temperature water approaches the lower part of the hot water storage tank 3. - 特許庁

The operation of the high-temperature boiling operation differs from that of the normal boiling operation in that the control device 10 forms the boiling circuit 4 for taking out the intermediate part and that the target boiling temperature is 65° C. or higher. . In the high-temperature boiling operation, medium-temperature water in the hot water storage tank 3 is taken out from the intermediate outlet 3e by driving the circulation pump 8, and the medium-temperature water pipe 40, the hot water lead-out pipe 42, the hot water lead-out pipe 34, the three-way valve 28, and the heat pump water inlet pipe 18 to the refrigerant-water heat exchanger 14 . In the refrigerant-water heat exchanger 14, the medium-temperature water is heated to the target boiling temperature by heat exchange with the refrigerant of the heat pump circuit to produce hot water, ie, high-temperature water. The generated hot water, ie, high-temperature water, flows into the upper portion of the hot water storage tank 3 via the heat pump hot water outlet pipe 19 , the second hot water pipe 45 and the fifth hot water pipe 48 . When the high-temperature boiling operation is executed, high-temperature water accumulates in the upper part of the hot water storage tank 3, and the position of the temperature boundary layer between the high-temperature water and the medium-temperature water gradually moves downward.

FIG. 3 is a diagram showing an example of fluctuations in the PV power generation amount, water heater power consumption amount, and indoor power consumption amount in one day. The example shown in FIG. 3 corresponds to an example in which the control device 10 changes the heating capacity of the heat pump unit 2 according to fluctuations in surplus power during execution of the surplus power boiling operation. That is, in the example shown in FIG. 3, the control device 10 adjusts the heating capacity of the heat pump unit 2 so that the sum of the electric power consumption of the hot water heater and the indoor electric power consumption other than the hot water heater does not exceed the PV power generation amount. are changing. As a result, it is possible to reliably prevent the purchase of commercial power for the boiling operation, which is advantageous in reducing electricity charges.

In the example shown in FIG. 3, the surplus electric power boiling operation is performed in the time period from about 9:00 to about 15:00. In this example, normal boiling operation is performed from about 9:00 to about 14:00, and high-temperature boiling operation is performed from about 14:00 to about 15:00, which is the final stage of boiling. The time period from about 19:00 to about 23:00 corresponds to a load generation time period in which a large amount of hot water supply load, hot water filling load, or reheating load tends to occur.

The higher the temperature in the hot water storage tank 3, the greater the tank heat radiation loss. In the present embodiment, since the high-temperature boiling operation is executed after the normal boiling operation, the high-temperature water generated by the high-temperature boiling operation is stored in the hot water storage tank 3 until the load generation time zone. can be shortened. For this reason, it becomes possible to reduce the tank heat radiation loss from the high-temperature water.

For the hot water supply load and the hot water filling load other than the reheating load, it is usually not necessary to use the high temperature water generated by the high temperature boiling operation. be. Also, in preparation for the reheating operation, it is desirable to preserve the high-temperature water in the hot water storage tank 3 as much as possible. From this point of view, when the hot water supply demand occurs before the reheating operation, the control device 10 can supply hot water using medium-temperature hot water generated in the normal boiling operation without using high-temperature water. desirable. That is, when the hot water supply operation or the hot water filling operation is performed before the reheating operation, the control device 10 sets the three-way valve 29 to bc, and the medium temperature water in the hot water storage tank 3 is discharged from the intermediate outlet 3e, The water is supplied to the bath hot water mixing valve 35 or the general hot water mixing valve 36 through the intermediate hot water pipe 40 and the water supply pipe 41 . At this time, the control device 10 adjusts the opening degree of the three-way valve 29 so that the set hot water supply temperature is achieved, and the low-temperature water from the water supply pipe 27 is supplied to the medium-temperature water from the medium-temperature water pipe 40. It may be configured to mix.

As in the example shown in FIG. 3, the time during which the normal boiling operation is executed is longer than the time during which the high-temperature boiling operation is executed among the hours during which the surplus power boiling operation is executed in a day. In general, the reheating load is much smaller than the sum of the hot water supply load and the hot water filling load. That is, the amount of hot water required is much less than the amount of medium temperature water required. Therefore, by making the time during which the high-temperature boiling operation is executed shorter than the time during which the normal boiling operation is executed, it is possible to suppress the generation of high-temperature water more than necessary, thereby further improving the energy efficiency.

The control device 10 adjusts the time for executing the normal boiling operation according to the predicted values of the hot water supply load and the hot water filling load, and executes the high temperature boiling operation according to the predicted value of the reheating load. You can adjust the time.

As in the example shown in FIG. 3, the control device 10 switches from the normal boiling operation to the high temperature boiling operation after the PV power generation amount has passed the peak of the day in the surplus power boiling operation. As a result, it is more advantageous to make the time during which the normal boiling operation is performed longer than the time during which the high temperature boiling operation is performed. The proportion with the amount of hot water produced by operation becomes more appropriate.

Further, in the surplus electric power boiling operation, the control device 10 switches from the normal boiling operation to the high temperature boiling operation after the amount of surplus electric power has passed the peak of the day. As a result, it is more advantageous to make the time during which the normal boiling operation is performed longer than the time during which the high temperature boiling operation is performed. The proportion with the amount of hot water produced by operation becomes more appropriate.

As described above, the high-temperature boiling operation is performed after the PV power generation amount or the surplus power amount has passed the peak of the day. Therefore, during the high-temperature boiling operation, it is necessary to lower the heating capacity of the heat pump unit 2 in order to reduce the power consumption of the water heater. In order to generate high temperature water with low heating capacity, it is necessary to reduce the boiling flow rate. The lower the boiling flow rate, the longer it takes for the high-temperature water from the heat pump unit 2 to flow into the hot water storage tank 3, resulting in a larger piping heat radiation loss.

FIG. 4 is a diagram schematically showing a state during high-temperature boiling operation. As shown in FIG. 4, where Two is the boiling temperature, Twi is the temperature of incoming water, V is the flow rate of boiling water, ρ is the density of water, and Cp is the specific heat of water, the heating capacity of the heat pump unit 2 is expressed by the following equation. be done.
Heating capacity = (Two-Twi) x V x ρ x Cp (1)

In the present embodiment, during the high-temperature boiling operation, the heat pump unit 2 heats medium-temperature water taken out from the intermediate outlet 3e of the hot water storage tank 3 to generate high-temperature water. Therefore, the incoming water temperature Twi during the high temperature boiling operation is higher than the incoming water temperature Twi during the normal boiling operation. As shown by the formula (1), if the incoming water temperature Twi increases, the boiling flow rate V is less likely to decrease even if the heating capacity is low. Thus, according to the present embodiment, it is possible to suppress the decrease in the boiling flow rate V during the high-temperature boiling operation, thereby reducing the piping heat radiation loss.

FIG. 5 is a diagram showing the relationship between Legionella spp. and water temperature. As shown in FIG. 5, if the water temperature is 60° C. or higher, Legionella bacteria are killed. If the water temperature is in the range of 50°C to 60°C, the Legionella spp. will soon die out, and if the water temperature is in the range of 45°C to 50°C, the Legionella spp. will not propagate. On the other hand, when the water temperature is in the range of 20°C to 45°C, Legionella tends to be active.

If the temperature of the medium-temperature water in the hot water storage tank 3 is 45° C. or lower, there is a possibility that the medium-temperature water contains Legionella bacteria. In contrast, in the present embodiment, during the high-temperature boiling operation, medium-temperature water taken out from the hot water storage tank 3 is heated by the heat pump unit 2 to generate high-temperature water. It is possible to reliably sterilize possible Legionella spp.

However, the present disclosure is not limited to the above example, and the low-temperature water taken out from the lower outlet 3d of the hot water storage tank 3 is supplied to the heat pump unit 2 during the high-temperature boiling operation of the surplus electric power boiling operation. It may be heated to produce hot water.

In the nighttime electricity rate time zone, the arithmetic processing unit 10b calculates the start time of the nighttime heating operation based on the target heat storage amount for the nighttime determined as described above. Then, when the start time comes, the arithmetic processing unit 10b sends an instruction to perform the boiling operation to the device control unit 10c. As described above, it is desirable for the arithmetic processing unit 10b to set the target boiling temperature during the nighttime boiling operation lower than the target boiling temperature during the high-temperature boiling operation. The arithmetic processing unit 10b may set the target boiling temperature for the nighttime boiling operation to be the same as the target boiling temperature for the normal boiling operation of the surplus power boiling operation. Moreover, it is desirable that the control device 10 keeps the heating capacity constant during the nighttime boiling operation. During execution of the nighttime boiling operation, the control device 10 terminates the boiling operation when the cumulative amount of heat to be boiled reaches the target heat storage amount for the nighttime.

FIG. 6 is a flowchart showing an example of processing executed by control device 10 when storage-type hot water supply apparatus 1 according to Embodiment 1 performs the surplus electric power boiling operation. A description will be given below based on this flow chart.

When the nighttime electricity rate period ends and it becomes the daytime period, in step S1, the control device 10 calculates the current surplus power based on the information on the amount of surplus power acquired by the information acquisition unit 10a or the communication unit 10d. Determine if the amount has reached a predetermined value. The predetermined value is a reference value for determining whether the boiling operation can be performed using surplus electric power. If the current amount of surplus power has reached the predetermined value, the process proceeds to step S2, and the control device 10 uses the surplus power to start normal boiling operation.

The control device 10 sets the target heating capacity of the heat pump unit 2 so that the electric power consumption of the water heater becomes equal to the surplus electric power during normal boiling operation. The surplus power amount changes from moment to moment. Therefore, the control device 10 repeatedly executes the adjustment of the target heating capacity every predetermined time. As a result, the surplus power can be used more effectively.

During execution of the normal boiling operation, in step S3, the control device 10 determines that the cumulative amount of heat accumulated after starting the normal boiling operation has reached the daytime target heat storage amount corresponding to the hot water supply load and the hot water filling load. to judge what If the accumulated boiling heat amount has not yet reached the daytime target heat storage amount, the control device 10 continues the normal boiling operation.

When the integrated boiling heat amount reaches the daytime target heat storage amount, the process proceeds to step S4, and the control device 10 switches from the normal boiling operation to the high temperature boiling operation. That is, the control device 10 changes the target boiling temperature to a value higher than that of the normal boiling operation, and switches the boiling circuit 4 from the lower extraction to the intermediate extraction. Even during the high-temperature boiling operation, the control device 10 repeatedly adjusts the target heating capacity at predetermined time intervals so that the electric power consumption of the water heater becomes equal to the surplus electric power amount. As a result, the surplus power can be used more effectively.

During execution of the high-temperature boiling operation, in step S5, the control device 10 determines whether or not the cumulative amount of heat generated after the start of the high-temperature boiling operation has reached the target heat storage amount of the high-temperature water corresponding to the reheating load. to decide. If the accumulated boiling heat amount has not yet reached the target heat storage amount corresponding to the reheating load, the control device 10 continues the high temperature boiling operation. When the cumulative boiling heat amount reaches the target heat storage amount corresponding to the reheating load, the process proceeds to step S6, and the control device 10 terminates the boiling operation. This completes the surplus power boiling operation.

Note that when the amount of PV power generation decreases and the amount of surplus power becomes equal to or less than the predetermined value in step S1 during the execution of the surplus power boiling operation, the control device 10 determines the accumulated amount of heat to be heated at that time. has not yet reached the target heat storage amount, either the normal boiling operation or the high-temperature boiling operation, which is being performed at that time, is continued. In this case, since no surplus power is generated, there is no need to constantly adjust the target heating capacity, so the control device 10 maintains the target heating capacity at a constant value.

FIG. 7 is a diagram showing an example of changes in temperature distribution in the hot water storage tank 3 from the start to the end of the boiling operation in the daytime. The example shown in FIG. 7 is as follows. At the start of the daytime boiling operation, medium-temperature water (45°C) generated by the nighttime boiling operation remains in the upper part of the hot water storage tank 3, and below that, low-temperature water (9°C) equivalent to tap water. °C). When the normal boiling operation is performed from this state, the low temperature water (9°C) in the hot water storage tank 3 decreases and the medium temperature water (45°C) increases. At the end of the normal boiling operation, the lower portion of the hot water storage tank 3 is filled with low-temperature water (9°C), and the upper portion is filled with medium-temperature water (45°C). When the high temperature boiling operation is performed from this state, part of the medium temperature water (45° C.) in the hot water storage tank 3 is taken out and heated by the heat pump unit 2 to become high temperature water (65° C.). When the high temperature boiling operation ends, the upper part of the hot water storage tank 3 is filled with high temperature water (65°C).

Next, the state change of the refrigerant circulating in the heat pump circuit during the boiling operation will be described. FIG. 8 is a Mollier diagram of the heat pump circuit of the hot water storage type hot water supply apparatus 1 according to the first embodiment. In FIG. 8, the horizontal axis is the enthalpy H [kJ/kg] and the vertical axis is the pressure P [MPa]. In FIG. 8, the broken line graph indicates the normal boiling operation, and the solid line graph indicates the high temperature boiling operation.

First, the normal boiling operation will be explained. The pressure and enthalpy of the refrigerant compressed by the compressor 13 change in the refrigerant-water heat exchanger 14 from x1' to x2'. In the refrigerant-water heat exchanger 14, the refrigerant exchanges heat with the water sent from the hot water storage tank 3, and is cooled to near the temperature of the water entering the refrigerant-water heat exchanger 14 (for example, 9°C) at maximum. . Within the refrigerant-water heat exchanger 14 the water is heated to near the inlet temperature of the refrigerant to the refrigerant-water heat exchanger 14 . The pressure and enthalpy of the refrigerant flowing into the expansion valve 15 change within the expansion valve 15 from x2' to x3. The refrigerant is depressurized in the expansion valve 15 and changes to a gas-liquid two-phase state.

The pressure and enthalpy of the refrigerant flowing into the outdoor heat exchanger 16 from the expansion valve 15 change from x3 to x4 within the outdoor heat exchanger 16 . In the outdoor heat exchanger 16, the refrigerant exchanges heat with the air sent by the outdoor heat exchanger fan 17, evaporates, and changes to a gas phase state.

The refrigerant pressure and enthalpy change in the compressor 13 from x4 to x1'. Inside the compressor 13, the refrigerant vapor heated by the outdoor heat exchanger 16 is compressed. The refrigerant vapor with increased pressure reaches the supercritical region and flows into the refrigerant-water heat exchanger 14 .

Next, the high-temperature boiling operation will be described, focusing on the differences from the normal boiling operation. In order to make the target boiling temperature higher than in the normal boiling operation, the compressor discharge temperature is made higher than in the normal boiling operation. Therefore, the discharge pressure and the enthalpy change from x1' to x1 compared to the normal boiling operation. When the temperature of the water flowing into the refrigerant-water heat exchanger 14 is constant near the temperature of tap water, even if the boiling temperature rises, the refrigerant enthalpy at the outlet of the refrigerant-water heat exchanger 14 does not change. . Therefore, the pressure and enthalpy of the refrigerant at the outlet of the refrigerant-water heat exchanger 14 change from x2' to x2 compared to normal boiling operation. Since the heat exchange capacity of the outdoor heat exchanger 16 does not change compared to the normal boiling operation, the pressure and enthalpy of the refrigerant at the inlet and outlet of the outdoor heat exchanger 16 are x3 and x3, respectively, as in the normal boiling operation. x4.

Embodiment 2.
Next, the second embodiment will be described with reference to FIG. 9, focusing on differences from the first embodiment described above, and common descriptions will be simplified or omitted. Moreover, the same code|symbol is attached|subjected to the element which is common with the element mentioned above, or corresponds.

FIG. 9 is a diagram showing an example of fluctuations in the PV power generation amount, water heater power consumption amount, and indoor power consumption amount in one day. The example shown in FIG. 9 shows an example in which the amount of solar radiation is small due to bad weather, the amount of PV power generation is low, and surplus power is not generated.

As in the example shown in FIG. 9, when the surplus power does not meet the criteria for executing the surplus power boiling operation and the heat storage amount in the hot water storage tank 3 is less than the target heat storage amount, the control device 10 , commercial power daytime heating operation, which is a heating operation using commercial power, is performed instead of the surplus power heating operation.

In the commercial power daytime heating operation, the control device 10 first performs the normal heating operation, and then performs the high temperature heating operation, as in the surplus electricity heating operation. That is, the control device 10 first performs the normal boiling operation so as to store the target heat storage amount in the daytime corresponding to the hot water supply load and the hot water filling load, and then sets the target heat storage amount of high-temperature water corresponding to the reheating load. Run hot boil operation to save.

According to this embodiment, the following effects can be obtained. In the normal boiling operation, since the boiling temperature is low, the COP of the heat pump unit 2 is increased, and the hot water discharged from the heat pump unit 2 dissipates and is lost while passing through the heat pump hot water discharge pipe 19. A piping heat radiation loss reducing effect that heat quantity is reduced and a tank heat radiation loss reducing effect that heat quantity lost by dissipation while hot water is stored in the hot water storage tank 3 are reduced. From these things, energy efficiency becomes high and the amount of power purchases can be suppressed.

In addition, since high-temperature water can be generated in the upper part of the hot water storage tank 3 by the high-temperature boiling operation after the normal boiling operation, the amount of heat exchanged in the bath heat exchanger 12 is sufficiently increased during the reheating operation. It is possible to perform appropriate reheating operation.

When performing the commercial electric power daytime heating operation, the control device 10 adjusts the start time of the commercial electric power daytime heating operation so that the commercial electric power daytime heating operation is completed by the load generation time zone. During the commercial power daytime heating operation, the control device 10 maintains a constant value of the target heating capacity because it is not necessary to change the heating capacity from moment to moment.

It should be noted that, among the plurality of embodiments described above, two or more that can be combined may be combined and implemented.

1 hot water storage type hot water supply device 2 heat pump unit 3 hot water storage tank 3a top 3b bottom 3c upper opening 3d lower outlet 3e intermediate outlet 4 boiling circuit 5 hot water storage temperature sensor 6 going water passage , 7 return water channel, 8 circulation pump, 9 hot water storage unit, 10 control device, 10a information acquisition unit, 10b arithmetic processing unit, 10c device control unit, 10d communication unit, 10e timer, 10f storage unit, 11 remote control, 12 bath heat exchange vessel, 13 compressor, 14 refrigerant-water heat exchanger, 15 expansion valve, 16 outdoor heat exchanger, 17 outdoor heat exchanger fan, 18 heat pump water inlet pipe, 19 heat pump hot water outlet pipe, 20 four-way valve, 22 bathtub circulation pump, 23 hot water supply end 24 water supply end 25 hot water supply pipe 26 hot water supply pipe 27 water supply pipe 28 three-way valve 29 three-way valve 30 four-way valve 31 tank water supply pipe 32 pipe 33 hot water introduction pipe 34 hot water outlet pipe , 35 bath hot water supply mixing valve, 36 general hot water supply mixing valve, 37 hot water supply pipe, 38 hot water supply opening/closing valve, 39 general hot water supply pipe, 40 intermediate water supply pipe, 41 water supply pipe, 42 hot water outlet pipe, 43 water pipe, 44 first Hot water pipe 45 Second hot water pipe 46 Third hot water pipe 47 Fourth hot water pipe 48 Fifth hot water pipe 49 Incoming water temperature sensor 50 Outgoing hot water temperature sensor 51 Bathtub temperature sensor 52 Outgoing bathtub temperature sensor 53 Hot water supply Flow rate sensor 54 Filled water flow rate sensor 55 Hot water supply temperature sensor 80 Bathtub unit 81 Bathtub 82 Tub going to tub 83 Bathtub return tubing 84 Drain plug

Claims (9)

a water storage tank;
heating means for heating the water taken out from the hot water storage tank;
a control means for controlling a boiling operation in which the hot water flowing out from the heating means flows into the hot water storage tank;
with
As the boiling operation, a normal boiling operation and a high-temperature boiling operation in which the boiling temperature, which is the temperature of the hot water flowing out of the heating means, is higher than that of the normal boiling operation can be performed,
In the surplus power boiling operation, which is the boiling operation using the surplus power of the power generated by the photovoltaic power generation device, the normal boiling operation is first performed, and after the normal boiling operation is performed, the high-temperature boiling is performed. A hot water storage type water heater that performs operation. The control means can adjust the heating capacity of the heating means,
2. The hot water storage type hot water supply apparatus according to claim 1, wherein said heating capacity is changed according to a change in said surplus electric power during execution of said surplus electric power boiling operation. The hot water storage tank has a lower outlet and an intermediate outlet above the lower outlet,
During the normal boiling operation, the water taken out from the lower outlet is heated by the heating means,
3. The hot water storage type hot water supply apparatus according to claim 1, wherein the water taken out from the intermediate outlet is heated by the heating means during the high temperature boiling operation. In the surplus power heating operation, after the amount of power generated by the solar power generation device has passed the peak of the day, or after the amount of surplus power has passed the peak of the day, the high-temperature boiling is performed from the normal heating operation. The hot water storage type hot water supply apparatus according to any one of claims 1 to 3, wherein the hot water supply apparatus is switched to a raising operation. 5. The method according to any one of claims 1 to 4, wherein the time during which the normal boiling operation is executed is longer than the time during which the high-temperature boiling operation is executed among the time during which the surplus power boiling operation is executed in a day. The hot water storage type hot water supply device according to the above item. Commercial power, which is the heating operation using commercial power instead of the surplus power heating operation when the surplus power does not meet the standard and the amount of heat stored in the hot water storage tank does not meet the target value. Execute the daytime heating operation,
6. The method according to any one of claims 1 to 5, wherein in the commercial power daytime heating operation, the normal heating operation is first performed, and after the normal heating operation is performed, the high-temperature heating operation is performed. Storage type water heater. Equipped with a bath heat exchanger that exchanges heat between the bath water from the bath and the heat medium,
7. A reheating operation of supplying high-temperature water, which is hot water stored in the hot water storage tank by the high-temperature boiling operation, to the bath heat exchanger as the heat medium is executed. The hot water storage type hot water supply device according to . When a demand for hot water supply occurs before the reheating operation, hot water is supplied using intermediate hot water, which is hot water stored in the hot water storage tank by the normal boiling operation, without using the high temperature water. Item 8. The hot water storage type hot water supply device according to Item 7. 9. The boiling temperature when performing the boiling operation using commercial power at night is lower than the boiling temperature during the high-temperature boiling operation. Storage type water heater.

Images